A new model to predict in vivo human knee kinematics under physiological-like muscle activation
A new model to predict in vivo human knee kinematics under physiological-like muscle activation
Although a number of approaches have attempted to model knee kinematics, rarely have they been validated against in vivo data in a larger subject cohort. Here, we assess the feasibility of four-bar linkage mechanisms in addressing knee kinematics and propose a new approach that is capable of accounting for lengthening characteristics of the ligaments, including possible laxity, as well as the internal/external rotation of the joint. MR scans of the knee joints of 12 healthy volunteers were taken at flexion angles of 0°, 30° and 90° under both passive and active muscle conditions. By reconstructing the surfaces at each position, the accuracy of the four-bar linkage mechanism was assessed for every possible combination of points within each cruciate ligament attachment area. The specific set of parameters that minimized the deviation between the predictions and the in vivo pose was derived, producing a mean error of 1.8 and 2.5 on the medial and 1.7 and 2.4 mm on the lateral side at 30° and 90° flexion, respectively, for passive motion, significantly improving on the models that did not consider internal/external rotation. For active flexion, mean medial errors were 3.3 and 4.7 mm and lateral errors 3.4 and 4.8 mm. Using this best parameter set, a generic predictive model was created and assessed against the known in vivo positions, producing a maximum average error of 4.9 mm at 90° flexion. The accuracy achieved shows that kinematics may be accurately reconstructed for subject specific musculoskeletal models to allow a better understanding of the load distribution within the knee.
knee, joint kinematics, four-bar linkage, mri, muscle, in vivo
S45-S53
Heller, M.O.
3da19d2a-f34d-4ff1-8a34-9b5a7e695829
König, C.
1d5d6617-571b-4b22-a1a2-083162035e7a
Graichen, H.
d62a3850-9400-467c-88e9-3664b2e64061
Hinterwimmer, S.
9af7a0ec-05d1-45d1-8783-0a9efc866ad9
Ehrig, R.M.
23abc0d9-47bd-427e-8edf-f334e0a87799
Duda, G.N.
32d09622-34ad-49dd-8314-3f61c99a764e
Taylor, W. R.
c56f0d4f-7a07-41cd-9312-06ee84a18ec6
2007
Heller, M.O.
3da19d2a-f34d-4ff1-8a34-9b5a7e695829
König, C.
1d5d6617-571b-4b22-a1a2-083162035e7a
Graichen, H.
d62a3850-9400-467c-88e9-3664b2e64061
Hinterwimmer, S.
9af7a0ec-05d1-45d1-8783-0a9efc866ad9
Ehrig, R.M.
23abc0d9-47bd-427e-8edf-f334e0a87799
Duda, G.N.
32d09622-34ad-49dd-8314-3f61c99a764e
Taylor, W. R.
c56f0d4f-7a07-41cd-9312-06ee84a18ec6
Heller, M.O., König, C., Graichen, H., Hinterwimmer, S., Ehrig, R.M., Duda, G.N. and Taylor, W. R.
(2007)
A new model to predict in vivo human knee kinematics under physiological-like muscle activation.
Journal of Biomechanics, 40 (Supplement 1), .
(doi:10.1016/j.jbiomech.2007.03.005).
Abstract
Although a number of approaches have attempted to model knee kinematics, rarely have they been validated against in vivo data in a larger subject cohort. Here, we assess the feasibility of four-bar linkage mechanisms in addressing knee kinematics and propose a new approach that is capable of accounting for lengthening characteristics of the ligaments, including possible laxity, as well as the internal/external rotation of the joint. MR scans of the knee joints of 12 healthy volunteers were taken at flexion angles of 0°, 30° and 90° under both passive and active muscle conditions. By reconstructing the surfaces at each position, the accuracy of the four-bar linkage mechanism was assessed for every possible combination of points within each cruciate ligament attachment area. The specific set of parameters that minimized the deviation between the predictions and the in vivo pose was derived, producing a mean error of 1.8 and 2.5 on the medial and 1.7 and 2.4 mm on the lateral side at 30° and 90° flexion, respectively, for passive motion, significantly improving on the models that did not consider internal/external rotation. For active flexion, mean medial errors were 3.3 and 4.7 mm and lateral errors 3.4 and 4.8 mm. Using this best parameter set, a generic predictive model was created and assessed against the known in vivo positions, producing a maximum average error of 4.9 mm at 90° flexion. The accuracy achieved shows that kinematics may be accurately reconstructed for subject specific musculoskeletal models to allow a better understanding of the load distribution within the knee.
This record has no associated files available for download.
More information
Published date: 2007
Keywords:
knee, joint kinematics, four-bar linkage, mri, muscle, in vivo
Organisations:
Bioengineering Group
Identifiers
Local EPrints ID: 348515
URI: http://eprints.soton.ac.uk/id/eprint/348515
ISSN: 0021-9290
PURE UUID: 6f8754ac-2d86-4ba0-a58d-4b86f0c1f2c3
Catalogue record
Date deposited: 26 Feb 2013 12:05
Last modified: 15 Mar 2024 03:43
Export record
Altmetrics
Contributors
Author:
C. König
Author:
H. Graichen
Author:
S. Hinterwimmer
Author:
R.M. Ehrig
Author:
G.N. Duda
Author:
W. R. Taylor
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics
